Data transmission method and data re-transmission method

ABSTRACT

A method which can reduce loss in data transmission is provided. A data block is prepared in a high-level layer and the data block is transmitted in a low-level layer. Status report information associated with reception or non-reception of the data block is received through the low-level layer. When a receiver fails to receive data transmitted from a transmitter, the transmitter can rapidly recognize the reception failure and can retransmit the data.

TECHNICAL FIELD

The present invention relates to wireless communication, and moreparticularly, to a data transmission method and a data retransmissionmethod which can reduce loss in data transmission.

BACKGROUND ART

A 3GPP (3-rd Generation Partnership Project) mobile communication systembased on a WCDMA (Wideband Code Division Multiple Access) radio accesstechnology has been widely spread all over the world. An HSDPA (HighSpeed Downlink Packet Access) which can be defined as a first evolutionstep of the WCDMA provides a radio access technology having a highcompetitive power in a mid-term future for the 3GPP. However, sincerequirements and expectations of users and providers have increased moreand more and competitive development of the radio access technology hasbeen made more and more, a new technological evolution of the 3GPP isrequired to enhance a high competitive power in the future.

The 3GPP entered into a project called “Evolved UTRA and UTRAN” from theend of 2004 for the purpose of development of a radio transmissiontechnology which can provide a high-quality service and reduce cost. Theproject of 3G long term evolution (hereinafter, referred to as LTE) aimsat expansion of a coverage, improvement of system capacity, decrease incost of users and providers and improvement in service quality. The 3GLTE defines as high-level requirements decrease in cost per bit,enhancement in service availability, flexible utilization of frequencybands, open interface with a simple structure and appropriate powerconsumption of by user equipments.

In any communication system, data can be lost in a physical channel.With the development of technologies, the probability that data are nottransmitted well from a transmitter to a receiver in the physicalchannel is lowered, but does not disappear completely. Particularly, incase of user equipments spaced apart from a base station, the data lossrate is high. Important signaling data or control signals need besubjected to more special management for the purpose of reliability ofthe communication systems.

One of techniques used to reduce the loss of data is an ARQ (AutomaticRepeat Request) method. Generally, the ARQ method is performed by ahigh-level layer. Lower-level layers perform HARQ (Hybrid ARQ), therebyreducing the loss of data. The HARQ uses a FEC (Forward ErrorCorrection) and the ARQ together to correct an error of data by the useof the FEC and to retransmit the data by the use of the ARQ.

When a receiver fails to receive data at the time of retransmission, thereception failure should be rapidly reported to a transmitter. This isbecause it is possible to reduce the time for correction of an error andthe time for solving an obstacle to data transmission by allowing thetransmitter to rapidly recognize the data reception failure. As thetransmitter recognizes more rapidly the reception failure, the time forretransmission is more reduced.

DISCLOSURE OF INVENTION Technical Problem

There is a need for technologies for enhancing reliability oftransmission by efficiently using the ARQ of the high-level layer andthe HARQ of the low-level layer.

Technical Solution

An advantage of some aspects of the invention is to provide a datatransmission method and a data retransmission method which canretransmit data, which are not received by a receiver, while efficientlyusing radio resources.

In an aspect of the invention, a data block is prepared in a high-levellayer and the data block is transmitted in a low-level layer. Statusreport information associated with reception or non-reception of thedata block is received through the low-level layer.

In another aspect of the invention, a RLC (Radio Link Control) PDU(Protocol Data Unit) is prepared in a RLC layer and the RLC PDU istransmitted using a HARQ (Hybrid Automatic Repeat Request) in a physicallayer. Status report information associated with reception ornon-reception of the RLC PDU is received. Whether the RLC PDU should beretransmitted is determined on the basis of the status reportinformation.

In still another aspect of the invention, a data block is retransmitteda data block through an HARQ by a preset number of times in a physicallayer. A reception of a NACK (Not ACKnowledgement) signal is reported toa RLC layer when receiving the NACK signal by the maximum allowablenumber of times. Whether the data block should be retransmitted isdetermined.

ADVANTAGEOUS EFFECTS

When a receiver does not receive data transmitted from a transmitter,the transmitter can rapidly confirm the reception failure and retransmitthe data. By transmitting status report information from the receiver tothe transmitter through a physical layer, it is possible to relativelyrapidly retransmit data. By providing operations of RLC entities forallowing data to arrive at the receiver without any error, it ispossible to more rapidly transmit data and to enhance the QoS (Qualityof Service).

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram illustrating a wireless communication system.

FIG. 2 is a block diagram illustrating a control plane of a radiointerface protocol.

FIG. 3 is a block diagram illustrating a user plane of the radiointerface protocol.

FIG. 4 is a flowchart illustrating a data transmission method accordingto an exemplary embodiment of the invention.

FIG. 5 is a flowchart illustrating a data transmission method accordingto another exemplary embodiment of the invention.

FIG. 6 is a flowchart illustrating an example of transmission andreception of status report information.

FIG. 7 is a flowchart illustrating another example of transmission andreception of status report information.

FIG. 8 is a flowchart illustrating a data transmission method accordingto another exemplary embodiment of the invention.

FIG. 9 is a flowchart illustrating a data transmission method accordingto another exemplary embodiment of the invention.

FIG. 10 is a block diagram illustrating a data transmission methodaccording to another exemplary embodiment of the invention.

FIG. 11 is a block diagram illustrating a handover according to anexemplary embodiment of the invention.

FIG. 12 is a diagram illustrating an example of a data transmissionmethod according to an exemplary embodiment of the invention.

FIG. 13 is a diagram illustrating an example of a data transmissionmethod according to an exemplary embodiment of the invention.

MODE FOR THE INVENTION

Hereinafter, exemplary embodiments of the invention will be described indetail with reference to the attached drawings.

FIG. 1 is a block diagram illustrating a wireless communication system.The wireless communication system may have a network structure of anE-UMTS (Evolved-Universal Mobile Telecommunications System). The E-UMTSmay be a long term evolution (LTE) system. The wireless communicationsystem is widely disposed to provide a variety of communication servicesof voices, packet data and the like.

Referring to FIG. 1, the E-UMTS network can be roughly classified intoan E-UTRAN (Evolved-UNITS Terrestrial Radio Access Network) and a CN(Core Network). The E-UTRAN includes eNode-B 20 and an AG (accessgateway) 30 which is located at the end of the network and connected toan external network.

A UE (User Equipment) 10 may be fixed or movable and can be calledvarious terminologies such as a mobile station (MS), a user terminal(UT), a subscriber station (SS) and a wireless device.

The eNode-B 20 generally means a fixed station communicating with the UE10 and can be called various terminologies such as a base station (BS),a base transceiver system (BTS) and an access point (AP). One or morecells may exist in one eNode-B 20. An interface for transmitting a usertraffic or a control traffic may be used between the eNode-Bs 20.

The AG 30 is also called MME/UPE (Mobility Management Entity/User PlaneEntity). The AG 30 may be divided into a portion for processing a usertraffic and a portion for processing a control traffic. The AG forprocessing the user traffic and the AG for processing the controltraffic can communicate with each other by the use of a new interface.

The CN may include the AG 30 and a node for registering for other UEs10. An interface for distinguishing the E-UTRAN and the CN from eachother may be used.

Layers of a radio interface protocol between the UE and the network canbe classified into an L1 layer (first layer), an L2 layer (secondlayer), and an L3 layer (third layer) on the basis of three low-levellayers of an open system interconnection (OSI) model widely known in thecommunication systems. A physical layer belonging to the first layerprovides an information transfer service using a physical channel and aRRC (Radio Resource Control) layer located in the third layer serves tocontrol radio resources between the UE and the network. The RRC layerinterchanges an RRC message between the UE and the network. The RRClayer can be distributed into the eNode-B and network nodes such as theAG or can be located locally in the eNode-B or the AG.

The radio interface protocol horizontally includes a physical layer, adata link layer, and a network layer. The radio interface protocolvertically includes a user plane for transmitting data and informationand a control plane for transmitting a control signal.

FIG. 2 is a block diagram illustrating a control plane of the radiointerface protocol. FIG. 3 is a block diagram illustrating a user planeof the radio interface protocol. FIGS. 2 and 3 illustrate a structure ofthe radio interface protocol between the UE and the E-UTRAN based on a3GPP radio network standard.

Referring to FIGS. 2 and 3, the physical layer as the first layerprovides an information transfer service to a high-level layer by theuse of a physical channel. The physical layer is connected to a MAC(Medium Access Control) layer as a higher-level layer through atransport channel. Data are transmitted between the MAC layer and thephysical layer through the transport channel. Data are transmittedbetween different physical layers, that is, between a transmission-sidephysical layer and a reception-side physical layer, through a physicalchannel.

The MAC layer of the second layer provides a service to a RLC (RadioLink Control) layer as a higher-level layer through a logical channel.The RLC layer of the second layer supports the data transmission withreliability. The function of the RLC layer may be embodied by afunctional block in the MAC layer and in this case, the RLC layer maynot exist.

A PDCP (Packet Data Convergence Protocol) layer of the second layerperforms a head compression function of reducing a head size of an IPpacket containing unnecessary control information with a relativelylarge size in order to efficiently transmit packets in a radio intervalhaving a small bandwidth at the time of transmitting an IP (InternetProtocol) packet such as IPv4 or IPv6.

The RRC layer located at the lowermost of the third layer is defined inonly the control plane. The RRC layer controls the logical channel, thetransport channel, and the physical channel associated with theconfiguration, re-configuration and release of the radio bearers (RB).The RB means a service provided from the second layer so as to transmitdata between the UE and the E-UTRAN.

A downlink transport channel for transmitting data from the network tothe UE can include a broadcast channel (BCH) for transmitting systeminformation and a downlink shared channel (SCH) for transmitting a usertraffic or a control message. The traffic or the control message of thedownlink multicast or the broadcast service may be transmitted throughthe downlink SCH or through a particular downlink MCH (MulticastChannel). An uplink transport channel for transmitting data from the UEto the network can include a random access channel (RACH) fortransmitting an initial control message and an uplink SCH (SharedChannel) for transmitting a user traffic or a control message.

The RLC layer has basic functions of guarantee of QoS (Quality ofService) of the RBs and transmission of data. Since the RB service is aservice which is provided to a higher-level layer from the second layerin the radio protocol, the entire second layer affects the QoS and theaffection of the RLC layer is the largest. The RLC layer has independentRLC entity for each RB so as to guarantee the QoS specific to the RB andthree RLC modes of a unacknowledged mode (UM), an acknowledged mode (AM)and a transparent mode (TM) so as to support a variety of QoS. Twomodes, that is, the UM not including an acknowledgement to transmitteddata and the AM including the acknowledgement, will be described below.

The UM RLC layer adds a PDU (Protocol Data Unit) header having asequence number to each PDU and thus informs a receiver of a lost PDU.For this reason, in the user plane, the UM RLC layer takes charge oftransmission of broadcast/multicast data or transmission of real-timepacket data such as voices (for example, VoIP) or streaming of a packetservice domain. In the control plane, the UM RLC layer takes charge oftransmission of an RRC message not requiring the acknowledgement amongthe RRC messages transmitted to a specific UE or a specific UE group ina cell.

Similarly to the UM RLC layer, the AM RLC layer adds a PDU header havinga sequence number at the time of constituting a PDU, but a receivertransmits the acknowledgement to the PDU transmitted from a transmitterunlike the UM RLC layer. This is designed to allow the receiver torequest the transmitter for retransmission of the PDU which is notreceived by the receiver. The AM RLC layer guarantees error-free datatransmission through retransmission and thus the AM RLC takes charge oftransmission of non-real-time packet data such as TCP/IP of the packetservice domain mainly in the user plane and can take charge oftransmission of RRC message requiring the acknowledgement.

In view of directionality, the UM RLC layer is used in a uni-directionalcommunication but the AM RLC is used in a bi-directional communicationdue to a feedback from the receiver. Since the bi-directionalcommunication is mainly used for a point-to-point communication, the AMRLC layer uses only a specific logical channel. In view of a structure,one RLC entity of the UM RLC layer has only one of transmission andreception, but one RLC entity of the AM RLC layer includes both oftransmission and reception.

The complexity of the AM RLC results from the ARQ function. The AM RLClayer has a retransmission buffer in addition to atransmission/reception buffer so as to manage the ARQ, and performs avariety of functions of utilization of a transmission/reception windowfor a flow control, polling of allowing a transmitter to request areceiver of a peer RLC entity of status information, status report ofallowing the receiver to report its buffer status to the transmitter ofthe peer RLC entity and piggyback of inserting the status PDU into thedata PDU so as to enhance the efficiency of data transmission. Inaddition, the functions of the AM RLC layer include a reset PUDrequesting the opposite AM RLC entity to reset all the operations andparameters when the AM RLC entity finds out an fatal error in the courseof operation and a reset ACK PDU used in acknowledgement of the resetPDU. In order to support the functions, the AM RLC requires a variety ofprotocol parameters, status variables and timers. The PDUs used forreport of the status information or control of the data transmission bythe AM RLC layer, such as the status PDU and the reset PDU are calledcontrol PDUs. The PDUs used for transmission of user data are calleddata PDUs.

Radio resources in one cell include uplink radio resources and downlinkradio resources. The eNode-B takes charge of assignment and control ofthe uplink radio resources and the downlink radio resources. The eNode-Bdetermines when a UE uses a radio resource, what a UE uses a radioresource and what radio resource a UE uses. For example, the eNode-B maydetermine that frequencies of 100 MHz to 101 MHz are assigned to the UEfor 0.2 seconds in 3.2 seconds for the downlink data transmission. Then,the base station informs the corresponding UE of the determinationdetails so as to allow the corresponding UE to receive the downlinkdata. Similarly, the eNode-B determines when a UE uses a radio resource,what a UE uses a radio resource and what radio resource a UE uses so asto transmit uplink data. The eNode-B transmits such information to thecorresponding UE. In this way, the eNode-B can dynamically manage theradio resources.

A conventional UE continuously used one radio resource during a callconnection. This is irrational in consideration of the fact that manyrecent services are based on IP packets. Most packet services do notcontinuously create packets during the call connection, but there aremany intervals where no data is transmitted. It is not efficient that aradio resource is continuously assigned to a UE. A method of assigning aradio resource to a UE only when service data exist can be used to solvethe above-mentioned problem.

The RLC entity constitutes a RLC PDU in accordance with the size of theradio resource determined by the MAC. The RLC entity located in theeNode-B constructs data with the size determined by the MAC entity andsends the RLC PDU to the MAC entity. The RLC entity located in the UEconstructs the RLC PDU in accordance with the size of a radio resourcedetermined by a lower-level layer, that is, the MAC entity. The RLCentity located in the UE constructs data with the size determined by theMAC entity and sends the RLC PDU to the MAC entity.

The MAC entity located in the UE receives information on the totalamount of radio resources from the eNode-B. The MAC entity receivesinformation indicating what amount of radio resources the MAC entity canuse at the next transmission time from the eNode-B. On the contrary, theMAC entity located in the eNode-B determines utilization of all of theuplink radio resources and the downlink radio resources. The MAC entityof the eNode-B determines what amount of radio resources should beassigned to the UE at the next transmission interval and sends thedetermination result to the MAC entities of the UEs. The UEs determinewhat amount of data should be transmitted through the logical channelsor by the RLC entities in consideration of data stored in their buffersand priorities thereof. Each RLC entity determines the size of the RLCPDU to be transmitted to the MAC entity. Similarly, the MAC entitylocated in the eNode-B determines what amount of data should be assignedto the respective RLC entities in consideration of the amount ofdownlink data of the respective UEs and the priorities of the data andsends the determination result to the respective RLC entities. Therespective RLC entities construct a RLC PDU in accordance with thedetermination result and transmit the constructed RLC PDU to the MACentity.

The PDU is a basic data unit used for data communication between layers.The PDU is a data which is transmitted from a corresponding layer to adifferent layer. A RLC PDU, a MAC PDU and the like are examples of thedata used by the layers. An SDU (Service Data Unit) is a data unit froma different layer to the corresponding layer.

FIG. 4 is a flowchart illustrating a data transmission method accordingto an exemplary embodiment of the invention. Tx RLC denotes a RLC entityin a transmitter 30 and Tx HARQ denotes a lower-level layer of the RLClayer for performing the HARQ in the transmitter 300. Rx RLC denotes aRLC entity in a receiver 350 and Rx HARQ denotes a lower-level layer ofthe RLC layer for performing the HARQ in the receiver 350. The HARQ ismainly performed in the physical layers. The HARQ operation may beperformed using the MAC PDU and the ARQ operation is at a level higherthan the HARQ operation.

Referring to FIG. 4, the RLC PDU is transmitted to the Tx HARQ from theTx RLC (S100). The RLC PDU is transmitted to the MAC layer and can beconverted into one or more MAC PDUs containing header information. TheMAC PDU serves as a data block to be transmitted from the physical layerthrough the HARQ. The Tx HARQ transmits a data block to the Rx HARQ(S110). When no error is detected from the received data block, the RxHARQ transmits an ACK (Acknowledgement) signal to the Tx HARQ and sendsthe data block to the Rx RLC as a higher-level layer. For clarity, it isassumed that an error is detected from the data block received by the RxHARQ.

When an error is detected from the data block, the Rx HARQ transmits anNACK (Not Acknowledgement) signal to the Tx HARQ (S120). The NACK signalserves as a retransmission request signal in the HARQ. The Tx HARQtransmits a retransmission data block to the Rx HARQ (S130). Theretransmission data block may be equal to or different from the datablock before the retransmission, depending on the HARQ method. When noerror is detected in the second transmission, the Rx HARQ transmits theACK signal to the Tx HARQ and sends the data block to the Rx RLC as ahigher-level layer. Here, it is assumed that an error is detected in thesecond transmission and the Rx HARQ transmits the NACK signal to the TxHARQ (S140).

In this way, the transmission may be repeated L times (S150). L denotesthe maximum allowable number of iteration. When an error is detected inthe L-th transmission, the Rx HARQ transmits the NACK signal to the TxHARQ (S160).

When receiving the N-th NACK signal, the Tx HARQ reports transmissionfailure to the Tx RLC (S170). The Tx RLC to which the transmissionfailure is reported sends the RLC PDU to the Tx HARQ again and startsthe retransmission (S180).

The Tx RLC sends the RLC PUD to the Tx HARQ (S180). The Tx HARQretransmits the data block to the Rx HARQ (S190).

When the transmitter 300 transmits a MAC PDU by the allowable number ofiteration and receives the NACK signal from the receiver 350 as many,the information is reported directly to the Tx RLC, not through the RxRLC. Since the information does not pass through the RLC entity of thereceiver 350, it is possible to check the necessity of retransmissionmore quickly. When the transmitter 300 starts directly new HARQtransmission in response to the NACK signal transmitted from thereceiver 350, the receiver 350 can more rapidly recognize a receptionerror.

On the other hand, the transmitter 300 retransmits a specific RLC PDUseveral times (N times) but may receive a response indicating that thespecific RLC PDU is not received by the receiver 350. When the RLC PDUis transmitted N times, the transmission is not performed any more andother data is transmitted. When the Tx RLC has transmitted the RLC PDU Ntimes and received a negative response in response thereto, the Tx RLCcan inform to the receiver 350 that the data is not transmitted anymore, without retransmitting the data. If the receiver 350 does not knowthat the transmission of data has been abandoned, the request forretransmitting the data may be transmitted to the transmitter 300.

When a certain condition occurs and the transmitter 300 does nottransmit a specific data block any more, the transmitter 300 may informthe receiver 350 of the fact. At this time, the transmitter 300 caninform the receiver 350 of the fact by the use of a header of a datablock or a control data block. The data block may be a RLC PDU or a MACPDU. The Rx LRC stops the waiting for the data block when receivinginformation indicating that a data block is not transmitted from thetransmitter 300. At this time, the receiver 350 can operate as if itreceived the data block. Alternatively, the receiver 350 may operate asif the data block was deleted. The receiver 350 may advance an window orreconstruct data regardless of the existence of the data block.

FIG. 5 is a flowchart illustrating a data transmission method accordingto another exemplary embodiment of the invention.

Referring to FIG. 5, the RLC PDU is sent from the Tx RLC to the Tx HARQ(S200). The Tx HARQ transmits a data block to the Rx HARQ (S210). Whenan error is detected from the data block, the Rx HARQ transmits a NACKsignal to the Tx HARQ (S220). The Tx HARQ transmits a retransmissiondata block to the Rx HARQ (S230). An error is detected in the secondtransmission and the Rx HARQ transmits the NACK signal to the Tx HARQ(S240). In this way, the transmission of the data block can be repeatedthe maximum allowable number of times L (S250).

An error is not detected in the final transmission and the data block issent to the Rx RLC (S255). The Rx HARQ transmits the ACK signal to theTx HARQ (S260). In step S260, the Tx HARQ may recognize the ACK signalas the NACK signal due to an influence of a physical channel. If the TxRLC to which the failure is reported retransmits the RLC PDU, it maywaste the radio resources.

In order to prevent the waste of radio resources, the Rx RLC constructsstatus report information and sends the status report information to theRx HARQ (S270). The Rx HARQ sends the status report information to theTx HARQ (S275). The status report information is information which istransmitted from the receiver 450 to the transmitter 400 and includesinformation on a data block received by the receiver 450 and a datablock not received by the receiver 450. The status report informationmay be constructed by the RLC layer or by the MAC layer. The receiver450 can allow only the information on the data block not received by thereceiver 450 to be included in the status report information. Since thedata loss in the physical layer is very small by using the HARQ, it maynot be efficient that the receiver 450 transmits all the information onthe data block received by the receiver 450 and the data block notreceived by the receiver 450. Additionally, when the receiver 450 shouldalso transmit information on the data block successfully received by thereceiver 450 in response to a request from the transmitter 400, thereceiver 450 can transmit the data block having the largest sequencenumber among the data blocks sequentially received.

The status report information is reported to the Tx RLC (S280). The TxRLC checks the status report information and then transmits thecorresponding RLC PDU. It is important to the ARQ method that when thereceiver 450 does not receive the data transmitted from the transmitter400, the transmitter 400 accurately and rapidly recognizes the failure.The Tx RLC can accurately and rapidly recognize whether the data shouldbe retransmitted, from the status report information transmitted throughthe physical layer.

The transmitter 400 should transmit an appropriate data block afterreceiving the status report information from the receiver 450. The TxRLC does not transmits the RLC SDU sent from the higher-level entity asit is, but reconstructs the RLC PDU with the size required by thelower-level entity and sends the reconstructed RLC PDU to thelower-level entity. For example, the RLC SDU with the size of 1000 bytescan be divided into several RLC PDUs. The receiver 450 may not receive apart of the RLC PDUs of the RLC SDU. For example, the receiver 450 maynot receive 100 bytes among 1000 bytes. In this case, it causes thewaste of radio resources that the transmitter 400 retransmits the entireRLC SDU. The receiver 450 sends information on the RLC PDUs not receivedby the receiver 450 to the transmitter 400 and the transmitter 400 thentransmits the corresponding RLC PDUs. When the radio resources are notsufficient, the transmitter 400 can transmit RLC sub-PDU into which theRLC PDU is divided.

The status report information is transmitted and received using thephysical layer so as to allow the transmitter 400 and the receiver 450to rapidly exchange the ARQ information. The status report informationcan be transmitted using a channel defined by the physical layer, not bythe level of the RLC PDU or the MAC PDU. When receiving the statusreport information, the physical layer sends the received status reportinformation to a higher-level RLC entity. When it is necessary totransmit status report information, the RLC entity sends the statusreport information directly to the physical layer and the physical layercan send the status report information using a physical channel otherthan the channel through which data are transmitted.

The status report information can be transmitted through a channelthrough which scheduling information indicating the assignment ofphysical resources in the physical layer is transmitted. The statusreport information may be information on a data block received or notreceived by the RLC entity of the receiver. Alternatively, the statusreport information may be information on a data block not to betransmitted by the RLC entity of the transmitter or information on adata block abandoned by the transmitter. When it is informed that aspecific data block is not transmitted from the transmitter any more,the RLC of the receiver 450 can stop the waiting of the RLC PDU andprocess the data blocks stored in its buffer.

The receiver 450 can add the status report information to a head portionof a data block. The data block may be a RLC PDU or a MAC PDU. Thestatus report information may be information on the data blocks notreceived by the receiver 450. The receiver 450 may not allow the statusreport information to include information on the data blocks received bythe receiver.

When the RLC entity or the logical channel is particularly mapped withthe HARQ process in order to reduce the overhead of the data blocks inthe high-level layers, several fields can be omitted. For example, whenRB 1 is mapped with HARQ process 1 in one to one, a TSN or a logicalchannel identifier can be omitted from the data block transmitted toHARQ 1.

The receiver uses the physical layer to more rapidly and effectivelysend the status report information. When a data block not received bythe receiver exists in the time interval received by the receiver, thereceiver may inform the transmitter of the fact by using a signalingthrough the physical channel. For example, when the receiver transmitssignals to the receiver through a physical control channel every timeinterval, the receiver can inform the transmitter whether the receiverreceives the data transmitted from the transmitter in the previous timeinterval through the physical channel. When the receiver informs thetransmitter that the receiver does not receive the data block in theprevious time interval through the physical channel, the transmitter canperform the retransmission of the data block. At this time, theinformation transmitted from the receiver to the transmitter indicatesin what time interval the receiver fails to receive the data block. Whenthe receiver fails to receive the data block transmitted from thetransmitter, the receiver may inform the transmitter of the informationon the time interval when the reception failure occurs.

In an exemplary embodiment, the information on the time intervaltransmitted from the receiver to the transmitter can include informationon the reception success and failure of the receiver for all thetransmission from the transmitter in the time interval, which is set ina constant size by the receiver, or occurrence time information thereof.In another exemplary embodiment, the information on the time intervaltransmitted from the receiver to the transmitter can include informationon the reception failure of the receiver for all the transmission fromthe transmitter in the time interval, which is set in a constant size bythe receiver, or occurrence time information thereof. In still anotherexemplary embodiment, the information on the time interval transmittedfrom the receiver to the transmitter can include information on thereception success and failure of the receiver for the transmission fromthe transmitter or occurrence time information thereof. In still anotherexemplary embodiment, the information on the time interval transmittedfrom the receiver to the transmitter can include information on thereception failure of the receiver for the transmission from thetransmitter or occurrence time information thereof.

When the transmitter receives the information on the reception failureor the time information thereof, the transmitter can make an appointmentof retransmission of the corresponding data regardless of the receptionof the status report information from the receiver. The transmission ofthe information on the reception failure or the time information thereofcan be performed by a physical layer or a MAC entity. A physical layeror a MAC layer of the transmitter having received the information on thereception failure or the time information thereof transmitted from thereceiver may inform the RLC layer of the information. The RLC entity ofthe transmitter having received the information on the reception failureor the time information thereof transmitted from the receiver mayretransmit the corresponding RLC PDU or RLC SDU and reconstruct the RLCPDU as needed.

FIG. 6 is a flowchart illustrating an example of transmission andreception of the status report information. The status reportinformation can be transmitted to the transmitter in a state where it isarbitrarily or previously set by the receiver. Alternatively, in orderto more rapidly check the status report information, the transmitter mayrequest for the transmission of the status report information throughstatus request information.

Referring to FIG. 6, the Tx HARQ transmits status request information tothe Rx HARQ (S310). The status request information request the receiverfor transmitting the status report information. The status requestinformation allows the transmitter 500 and the receiver 550 to morerapidly exchange the status report information. The status requestinformation is information indicating that the receiver 550 shouldrapidly construct and transmit the status report information. Whenreceiving the status request information, the Rx HARQ informs the Rx RLCof the fact (S320). The Rx RLC constructs and sends the status reportinformation to the Rx HARQ (S330). The Rx HARQ transmits the statusreport information (S340).

When a predetermined condition is satisfied, the physical layer of thetransmitter 500 can transmit the status request information through aphysical channel different from the physical channel through which dataare transmitted. For example, when the physical layer performs theretransmission the same number of times as the maximum number of timesof HARQ retransmission set in the data block transmitted by the physicallayer, the physical layer can set and transmits the status requestinformation.

The status report information or the status request information can betransmitted through a control information transport channel which isused in the physical layer to transmit the scheduling information.

FIG. 7 is a flowchart illustrating another example of transmission andreception of the status report information.

Referring to FIG. 7, the Tx RLC requests for the status requestinformation (S410). The status request information may be requested by ahigher-level layer as well as the physical layer. When the buffer of theRLC entity is empty, for example, when the final RLC PDU has beentransmitted, the RLC entity can request for the status requestinformation so as to receive the status report information from thereceiver 650. The Tx HARQ transmits the status request information tothe Rx HARQ (S420). When receiving the status request information, theRx HARQ informs the Rx RLC of the fact (S430). The Rx RLC constructs andsends the status report information to the Rx HARQ (S440). The Rx HARQtransmits the status report information (S450).

FIG. 8 is a flowchart illustrating a data transmission method accordingto another exemplary embodiment of the invention.

Referring to FIG. 8, the RLC PDU is sent from the Tx RLC to the Tx HARQ(S500). The Tx HARQ transmits a data block to the Rx HARQ (S510). Whenan error is detected from the data block, the Rx HARQ transmits an NACKsignal to the Tx HARQ (S520). The Tx HARQ transmits the retransmissiondata block to the Rx HARQ (S530). An error is detected in the secondtransmission and the Rx HARQ transmits the NACK signal to the Tx HARQ(S540). In this way, the transmission can be repeated by L times whichis the maximum allowable number of times (S550).

When an error is detected in the final transmission, the Rx RLC isrequested for constructing the status report information (S555). The RxRLC constructs and sends the status report information to the Rx HARQ(S570). When an error is detected and the Rx HARQ transmits the NACKsignal, the Tx HARQ may recognize the NACK signal as the ACK signal(S560). The Rx HARQ transmits the status report information to the TxHARQ (S575). The status report information is reported to the Tx RLC(S580). Accordingly, even when an error occurs from the ACK/NACK signal,the RLC can accurately judge whether the retransmission should beperformed on the basis of the status report information.

Independently of the status report information, the physical layer cantransmit particular information to more effectively transmit theACK/NACK signals between the HARQ. When the transmitter performs thefinal HARQ process of a specific data block, the transmitter cantransmit particular information indicating that the final HARQ of thespecific data block is being transmitted, through the physical layer.

FIG. 9 is a flowchart illustrating a data transmission method accordingto another exemplary embodiment of the invention. It relates to a methodof allowing the RLC entity to cope with an emergency.

Referring to FIG. 9, the Tx RLC transmits a RLC PDU to the receiver 850(S600). When the first transmission fails, the Tx RLC performs theretransmission. The retransmission can be repeated by N times which isthe maximum allowable number of times (S610). When the N-th transmissionfails, the Tx RLC informs the Rx RRC of the failure (S630).

When the case where the transmitter 800 transmits a specific data blockbut does not receive an acknowledgement from the receiver 850 isrepeated a predetermined number of times or more, the RLC layer mayinform a higher-level layer of resetting a communication condition. Whenthe RRC is informed by the RLC that it transmits a data block apredetermined number of times or more but does not receive anacknowledgement from the opposite party, the RRC solve this problem byusing the RRC signaling of the higher-level layer. The RRC signalingmeans that the transmitter and the receiver transmit an RRC message toeach other. In this case, the RRC can reset the RLC.

When transmitting the specific data block several times but notreceiving an acknowledgement from the receiver 850, the Tx RLC may stopthe transmission of the data block. Tx RLC may inform the Tx RRC as ahigher-level layer of this fact, and waits for an instruction therefrom.Alternatively, when recognizing an abnormal operation in thetransmission of the specific data block, the Tx RLC may not process sucha situation, but inform the RRC as a higher-level layer of the situationand comply with an instruction therefrom.

FIG. 10 is a block diagram illustrating a data transmission methodaccording to another exemplary embodiment of the invention.

Referring to FIG. 10, the transmitter sequentially transmits RLC PDU0,RLC PDU1, RLC PDU2, RLC PDU3, and RLC PDU4 and the receiver receivessuccessfully RLC PDU0 and RLC PDU1 but fails to receive RLC PDU2. Sincefailing to receive RLC PDU2, the receiver loads the information on RLCPDU2 to the status report information.

RLC PDU2 includes a part of RLC SDU1 and a part of RLC SDU2. When thereceiver transmits the status report information based on theinformation of the SDU, the receiver should transmit at least twoinformation pieces, that is, information pieces on RLC SDU0 and RLCSDU1. On the contrary, when the receiver transmits the status reportinformation based on the information of the PDU, the receiver cantransmit only one information piece, that is, the information on the RLCPDU2. Accordingly, by transmitting the status report information basedon the information of the PDU, it is possible to reduce the amount ofdata to be transmitted.

The PDU can be expressed in various ways. For example, the PDU can beexpressed as what portion of the SDU is addressed by the data includedin the PDU or as sequence number assigned to each PDU. In order to allowthe transmitter and the receiver to easily manage the PDUs, the statusreport information can be managed based on the sequence numbers.

FIG. 11 is a block diagram illustrating a handover.

Referring to FIG. 11, a source eNode-B 910 denotes an current eNode-Band a target eNode-B 920 denotes a new base station after the handover.When the source eNode-B 910 and the target eNode-B 920 have differentinformation associated with the status report information of a UE 900 orthe target eNode-B 920 does not have the latest status reportinformation, unnecessary transmission may cause. The transmission of newdata may be delayed due to the unnecessary transmission, therebydeteriorating the QoS. When a handover occurs, the UE 900 retransmitsthe SDUs, for which no acknowledgement is received from the sourceeNode-B to the target eNode-B 920.

The UE 900 can reconstruct the RLC SDU into the RLC PDU and transmit thereconstructed RLC PDU to the target eNode-B 920. Alternatively, thesource eNode-B 910 can transmit the latest status report information tothe target eNode-B 920 and the target eNode-B 920 can transmit thelatest status report information to the UE 900.

The SDU which is transmitted from the eNode-B to the AG in the course ofthe handover can be classified into two kinds, that is, SDU which thesource eNode-B 910 transmits to the AG 930 and SDU which the targeteNode-B 920 transmits to the AG 930. When the handover does not occur,the eNode-B rearranges the SDU received from the UE, but when thehandover occurs, both eNode-Bs transmit the SDU to the AG 930 and thusany eNode-B cannot rearrange the SDU. The AG 930 should check all theSDUs transmitted from the source eNode-B 910 and the target eNode-B 920and rearrange the SDUs. Right after the handover, the target eNode-B 920transmits the SDU to the AG 930 every when restoring the SDUs, for apredetermined time, that is, until the handover is completed.

The target eNode-B 920 can transmit to the AG 930 the RLC SDUs receivedsuccessfully itself by the use of the time information of the handover.The time information of the handover can be received from the sourceeNode-B 910.

The target eNode-B 920 can transmit the RLC SDU successfully receivedfrom the UE 900 to the AG 930 at once for a predetermined time after thehandover is made. The time information can be used to determine how longthe target eNode-B 920 transmits the RLC SDU successfully received tothe AG 930. The time information may be valid from the time point whenthe instruction for the handover is received from the source eNode-B910. Alternatively, the time information may be valid from the timepoint when the target eNode-B 920 receives a message associated with thehandover from the UE 900.

For a predetermined time from the time point when the UE 900 accessesthe target eNode-B 920, the target eNode-B 920 may not rearrange buttransmit the RLC SDU successfully received from the UE 900 to the AG 930at once. The target eNode-B 920 may receive the time information fromthe source eNode-B 910 and not rearrange but transmit the RLC SDUsuccessfully received from the UE 900 to the AG 930 at once until thetime point instructed by the time information. After the predeterminedtime, the target eNode-B 920 may rearrange and transmit the successfullyreceived RLC SDU to the AG 930.

When receiving the RLC SDU having a sequence number smaller than thesequence number designated by the source eNode-B 910, the target eNode-B920 can transmit the received RLC SDU to the AG 930 at once. The UE 900transmits the sequence number information at the time of accessing thetarget eNode-B 920 and the target eNode-B 920 can transmit the receivedRLC SDU to the AG 930 at once when receiving the RLC SDU having asequence number smaller than the sequence number. The UE 900 can informthe target eNode-B 920 of the largest sequence number of the sequencenumbers of the RLC SDUs which have been transmitted to the sourceeNode-B 910 at the time of first accessing the target eNode-B 920.

On the other hand, the optimization process may be carried out in thedownlink direction. In a new cell, the UE 900 transmits a handovercompletion message to the target eNode-B 920. In the course, the targeteNode-B 920 transmits a response message to the handover completionmessage. The UE 900 informs the target eNode-B 920 of the largestsequence number of the sequence numbers of the SDUs successfully andcontinuously received by the UE 900 for the downlink data successfullyreceived by the UE 900. The target eNode-B 920 can newly transmit onlythe SDUs having a sequence number larger than the acquired sequencenumber to the UE 900. It is possible to reduce the burden of the UE 900which classifies and rearranges the SDUs received from the targeteNode-B 920 and the source eNode-B 910.

Hereinafter, operation of the ARQ and the HARQ is described.

The HARQ with an N-channel SAQ (Stop-And-Wait) is advantageous for ahigher transmission rate. In the HARQ, while one process performs thetransmission and then waits for a response thereto, another processperforms the transmission. By reducing idle time in the transmission, itis possible to enhance the transmission rate. However, since the radioconditions are often changed, the qualities of radio intervals to beactually experienced may be different from each other between continuousprocesses. Accordingly, the process having started the transmission doesnot always finish the transmission earlier. Therefore, the receivershould be able to perform the rearrangement and thus includes a bufferfor performing the rearrangement.

The ARQ entity, that is, the RLC entity operating in the AM mode,includes a buffer. This is because all the portions of the SDU should bestored in the buffer of the receiver until all the PDUs including aspecific portion of the SDU arrive. If a gap occurs in the buffer of thereceiver, it means that a specific RLC PDU is not received. If a gapoccurs in the buffer of the HARQ, it also means that a specific MAC PDUis not received. Since the RLC PDUs constitute the MAC PDUs, the gap inthe RLC buffer and the gap in the HARQ buffer are associated with eachother. It is possible to perform the buffer management in comprehensiveconsideration of two gaps. The rearrangement in the HARQ and the RLCPDUs received by the RLC can be simultaneously considered using only onebuffer.

The MAC PDUs are decomposed as soon as being received and then are sentto the RLC entities. In order for the RLC entity to solve the gapgenerated due to the N-channel SAW in the MAC, the RLC entity shouldcheck whether the gap generated in the RLC buffer is due to thereception failure or the inversion of transport order generated due tothe N-channel SAW. The buffer of the RLC entity can use a timer. When agap is generated in the buffer of the RLC entity, the timer is activatedat once. When data corresponding to the gap is not received until thetimer expires, it is judged that the gap is generated due to thereception failure and the status report information may be transmittedto the transmitter.

FIG. 12 is a diagram illustrating an example of a data transmissionmethod according to an exemplary embodiment of the invention, where aMAC layer (Rx MAC) and a RLC layer (Rx RLC) in the receiver are shown.

Referring to FIG. 12, in {circle around (1)}, the ARQ entity, that is,the RLC entity, receives PDU3 from the HARQ as a lower-level layer, thatis, the MAC layer. Since PDU2 having a sequence number smaller than thatof PDU3 does not exist, the receiver checks that the gap is generateddue to the inversion of transport order of the HARQ by the use of theHARQ jitter timer JT.

In {circle around (2)}, the RLC entity receives PDU2 before the HARQjitter timer JT expires, and the HARQ jitter timer JT stops.

In {circle around (3)}, similarly to {circle around (1)}, since the ARQentity received PDU6 having a sequence number smaller than that of PDU7,the HARQ jitter timer JT is activated.

In {circle around (4)}, although the HARQ jitter timer JT expires, theRLC entity cannot receive PDU6. The receiver judges that the receptionof PDU6 fails and transmits the status report information associatedtherewith to the transmitter.

When receiving the status report information indicating that thereceiver does not receive a certain PDU from the receiver, thetransmitter retransmits the corresponding PDU. A timer may be set ineach data block so as to prevent a deadlock. When the timers set in theSDUs expire, the pieces of the SDUs are not transmitted any more evenwhen the reception failure is reported from the receiver.

When receiving a data block having a sequence number outside the currentwindow, the receiver adjusts the boundary of the window. The operationof the receiver uses the timer and the reception window.

FIG. 13 is a diagram illustrating an example of a data transmissionmethod according to an exemplary embodiment of the invention, where RLCsserving as an AM in the transmitter and the receiver are shown.

Referring to FIG. 13, in {circle around (1)}, SDU1 arrives at the bufferof the transmitter and a discard timer DT is activated. In {circlearound (2)}, SDU2 arrives at the buffer of the transmitter and a discardtimer DT is activated. The discard timers DT serve to define the maximumdelay time set in the RLC entities.

In {circle around (3)}, the receiver receives PDU3 and recognizes thatPDU2 having a sequence n umber smaller than that of PDU3 dose not arriveyet. In order to check whether the reception failure is generated due tothe inversion of transfer order of the HARQ, the receiver starts theHARQ jitter timer JT.

In {circle around (4)}, when the HARQ jitter timer JT expires, thereceiver reports to the transmitter that it does not receive PDU2. Atthe same time, in order to prevent the report from being lost, aperiodic timer PT for PDU2 is activated.

In {circle around (5)}, the transmitter receives the report transmittedfrom the receiver. Since the discard timer DT for SDU1 does not expireyet, the transmitter retransmits PDU2.

In {circle around (6)}, the discard timer DT for SDU1 expires. Thepieces of SDU1 are not transmitted any more. At this time, thetransmitter may inform the receiver that the discard timer DT for SDU1expires and thus it does not transmit the pieces of SDU1 any more. It ispossible to prevent waste of radio resources by preventing anunnecessary retransmission request.

In {circle around (7)}, the periodic timer PT for PDU2 expires. Sincethe receiver does not receive PDU2 hitherto, the receiver transmits thestatus report information for PDU2 again. The periodic timer PT may beactivated again at the same time of transmitting the status reportinformation.

In {circle around (8)}, since the transmitter receives the status reportinformation transmitted from the receiver again but the transmitterdiscards SDU1 due to the expiration of the discard timer DT, PDU2 is notretransmitted any more.

In {circle around (9)}, a release timer RT for SDU2 expires in thereceiver. The release timer RT is activated when the successfullyreconstructed SDU cannot be sent to a higher-level layer because an SDUhaving a sequence number smaller than that thereof does not arrive atthe receiver. For example, the receiver successfully receives SDU2 byreceiving a part of PDU3, PDU4, and PDU5, the receiver does not completethe reception of SDU1 having a sequence number smaller than that of SDU2because not receiving PDU2. At the time of receiving SDU2, the releasetimer RT is activated. The release timer RT is used to prevent a certainSDU from staying in the buffer of the receiver too long. When therelease timer RT expires, the receiver sends succeeded SDU2 to ahigher-level layer and does not wait for failed SDU1 or PDUs associatedthe failed SDU (PDU2) any more. Since not waiting PDU2 any more, theperiodic timer PT is also stopped.

It is possible to manage the retransmission request by the use of onlythe buffer of the RLC layer without using the buffer of the MAC layer.

The ARQ used here may be a NACK based system. The NACK based system iseffective when data are steadily transmitted. More fine operations arerequired in consideration of transmission of packets or user datatransmitted intermittently or the final SDU or PDU of a certain dataflow. The NACK based system can be used when certain data is notreceived and the reception failure is checked by the receiver.

The receiver transmits the status report information as information ondata not received. When the transmission of data is intermittent, thatis, when the size of data is very small, the receiver may not know thetransmission of data itself and the receiver cannot thus transmit thestatus report information. In this case, the receiver needs to reportthe transmitter that the receiver receives the data successfully. Thetransmitter also needs to request the receiver to transmit the statusreport information. In an exemplary embodiment, a PDU may contain acommand for requesting the receiver to transmit the status reportinformation. In another exemplary embodiment, for the purpose of morerapid transmission, the transmitter may directly command the receiver totransmit a report through a physical channel through which thescheduling information is transmitted.

The receiver should transmit the status report information to thetransmitter as soon as it receives the request for the status reportinformation. When not receiving the status report information within apredetermined time, the transmitter can automatically retransmit thedata. When the timer is used, the retransmission can be performedregardless of the status report information.

The present invention can be embodied in hardware, software, orcombinations thereof. Examples of the hardware can include an ASIC(Application Specific Integrated Circuit), a DSP (Digital SignalProcessing), PLD (Programmable Logic Device), an FPGA (FieldProgrammable Gate Array), a processor, a controller, a micro processor,other electronic units, and combinations thereof, which are designed toperform the above-mentioned functions. In software, the invention can beembodied by modules for performing the above-mentioned functions. Thesoftware can be stored in a memory unit and executed by a processor. Asthe memory unit or processor, means well known to those skilled in theart can be employed.

Although the embodiments of the present invention have been described indetail with reference to the attached drawings, it should be understoodby those skilled in the art that the invention can be modified andchanged in various forms without departing from the technical spirit andscope of the invention. Accordingly, the invention is not limited to theabove-mentioned embodiments, but includes all the embodiments withoutdeparting from the scope of the appended claims.

1-15. (canceled)
 16. A method of communication performed by a receiverin a wireless communication system, the method comprising: receiving atleast one data block at a Medium Access Control (MAC) layer by usingHybrid Automatic Repeat Request (HARQ); delivering the at least one datablock from the MAC layer to a Radio Link Control (RLC) layer;constructing an RLC Protocol Data Unit (PDU) from the at least one datablock; placing the RLC PDU in a reception buffer if a Sequence Number(SN) of the RLC PDU is within a reception window; updating the receptionwindow if the RLC PDU is placed in the reception buffer; and stopping atimer if the reception window is moved while the timer is running,wherein the timer is started if at least one RLC PDU in the receptionwindow is detected as missed.
 17. The method of claim 16, furthercomprising moving the reception window if a lower edge of the receptionwindow is updated as a new SN.
 18. The method of claim 17, wherein thelower edge of the reception window is an SN following a last in-sequencecompletely received RLC PDU.
 19. The method of claim 17, wherein the newSN is equal to an SN following an SN of an RLC PDU with a highest SNamong received RLC PDUs when the timer is started.
 20. The method ofclaim 19, wherein the new SN is an SN following the SN of the RLC PDUplaced in the reception buffer.
 21. The method of claim 16, wherein thereception window is not moved if an SN following the SN of the RLC PDUplaced in the reception buffer is equal to an SN following an SN of anRLC PDU with a highest SN among received RLC PDUs when the timer isstarted.
 22. The method of claim 16, further comprising: transmitting astatus report for Automatic Repeat Request (ARQ) to a transmitter afterthe timer expires.
 23. A receiver in a wireless communication system,the receiver comprising a Medium Access Control (MAC) entity and a RadioLink Control (RLC) entity, wherein the MAC entity is configured to:receive at least one data block by using Hybrid Automatic Repeat Request(HARQ); and deliver the at least one data block to the RLC entity; andwherein the RLC entity is configured to: construct an RLC Protocol DataUnit (PDU) from the at least one data block; place the RLC PDU in areception buffer if a Sequence Number (SN) of the RLC PDU is within areception window; update the reception window if the RLC PDU is placedin the reception buffer; and stop a timer if the reception window ismoved while the timer is running, wherein the timer is started if atleast one RLC PDU in the reception window is detected as missed.
 24. Thereceiver of claim 23, wherein the reception window is moved if a loweredge of the reception window is updated as a new SN.
 25. The receiver ofclaim 24, wherein the lower edge of the reception window is an SNfollowing a last in-sequence completely received RLC PDU.
 26. Thereceiver of claim 24, wherein the new SN is equal to an SN following anSN of an RLC PDU with a highest SN among received RLC PDUs when thetimer is started.
 27. The receiver of claim 26, wherein the new SN is anSN following the SN of the RLC PDU placed in the reception buffer. 28.The receiver of claim 23, wherein the reception window is not moved ifan SN following the SN of the RLC PDU placed in the reception buffer isnot equal to an SN following an SN of an RLC PDU with a highest SN amongreceived RLC PDUs when the timer is started.
 29. The receiver of claim23, wherein the RLC entity is further configured to transmit a statusreport for Automatic Repeat Request (ARQ) to a transmitter after thetimer expires.